Method, baseboard management controller and system for establishing a serial-over-lan connection

ABSTRACT

A method, a baseboard management controller (BMC) and a system for establishing a serial-over-LAN connection are provided. The method includes: receiving data from a server unit using the first UART at a current baud rate; detecting the current baud rate of the first UART using the BMC; configuring the baud rate of the second UART of the BMC as the current baud rate; controlling the second UART to retrieve the data from the first UART at the current baud rate using the BMC; and sending the data to a network using the BMC.

FIELD OF THE INVENTION

The present invention relates to a method for realizing serial-over-LAN(SOL) and a baseboard management controller (BMC) for performing themethod, and more particularly to a method and a BMC for realizing SOLwith enhanced efficiency.

BACKGROUND

Intelligent Platform Management Interface (IPMI) is a set of computerinterface specifications often used to manage a network of computingdevices for diagnostic or maintenance purposes. An IPMI includes mainlya baseboard management controller (BMC) and other controller components.The BMC is a specialized microcontroller embedded on the motherboard ofa computer and independent of the operating system thereof. In general,when a remote diagnostic or maintenance procedure is required, theSerial-over-LAN (LAN) mechanism can be requested by the remotemanagement platform, in which the BMC, upon receiving the request,controls the serial communication between the computing device and theserial port to be redirected to the LAN via the BMC UART.

Oftentimes, manually configuring the baud rate of the BMC UART isrequired. The reason is that the baud rate of the system UART, i.e. theUART that receives host data, is controlled by the host, and thus maychange. If the baud rate at which the BMC UART receives the host data isdifferent from the baud rate of the system UART, error may exist in thereceiving of the host data. Therefore, the efficiency of establishingthe SOL connection in the prior art is low due to the need to constantlytry and adjust the baud rate of the BMC UART.

SUMMARY

Accordingly, one of the objectives of the present invention is toprovide a method for establishing a Serial-over-LAN (SOL) connection,and a baseboard management controller (BMC) and a system for performingthe method, in which automatic SOL connection is realized upon an SOLrequest, thereby enhancing the efficiency in the establishment of SOLconnection.

One embodiment of the present invention provides a method forestablishing an SOL connection. The method comprises receiving data froma server unit using a first UART at a current baud rate; detecting thecurrent baud rate of the first UART using a BMC; configuring the baudrate of a second UART as the current baud rate using the BMC;controlling the second UART to retrieve the data from the first UART atthe current baud rate using the BMC; and sending the data to a networkusing the BMC.

Another embodiment of the present invention provides a BMC including asecond UART, a control module and a network interface. The second UARTis configured to receive data from a first UART, the first UARTreceiving the data from a server unit. The control module is connectedto the second UART and configured to detect a current baud rate of thefirst UART and control the second UART to receive the data from thefirst UART at the current baud rate. The network interface is connectedto the control module, configured to receive the data from the controlmodule and send the data to a network.

Another embodiment of the present invention provides a system forestablishing an SOL connection. The system includes a server unit and aremote control unit. The server unit has a computing module, a firstUART and a BMC. The first UART is electrically connected to thecomputing and configured to receive data from the computing module. TheBMC is connected to the computing module, and includes a second UART, acontrol module and a network interface. The second UART is configured toreceive the data from the first UART. The control module is connected tothe second UART and configured to detect a current baud rate of thefirst UART and control the second UART to receive the data from thefirst UART at the current baud rate. The network interface is connectedto the control module and configured to receive the data from thecontrol module and send the data to a network. The remote control unitis electrically connected to the BMC and configured to receive the datafrom the network interface through the network.

In order to further the understanding of the present disclosure,reference is made to the following detailed description illustrating theembodiments and examples of the present disclosure. The description isfor illustrative purpose only and is not intended to limit the scope ofthe claim.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a functional block diagram of a system for establishing anSOL connection according to one embodiment of the present invention.

FIG. 2 shows a flow chart illustrating a method for establishing an SOLconnection according to one embodiment of the present invention.

FIG. 3 shows a flow chart illustrating a method for detecting thecurrent baud rate of the first UART according to one embodiment of thepresent invention.

FIG. 4A shows a flow chart illustrating a method of determining theswitching range of the first set of data according to one embodiment ofthe present invention.

FIG. 4B to FIG. 4E illustrate the switch unit of the sample bytes of thefirst set of data according to several embodiments of the presentinvention.

FIG. 5 illustrates one embodiment of the step of detecting the currentbaud rate of the first UART according to the present invention.

FIG. 6 illustrates one embodiment of detecting the current baud rate ofthe first UART according to the present invention.

FIG. 7 illustrates one embodiment of detecting the current baud rate ofthe first UART according to the present invention.

FIG. 8 illustrates one embodiment of detecting the current baud rate ofthe first UART according to the present invention.

FIG. 9 illustrates one embodiment of detecting the current baud rate ofthe first UART according to the present invention.

FIG. 10 illustrates one embodiment of determining the current baud rateof the first UART according to the present invention.

FIG. 11 shows a functional block diagram illustrating the BMC accordingto a varied embodiment of the present invention.

DETAILED DESCRIPTION OF EMBODIMENTS

The aforementioned illustrations and following detailed descriptions areexemplary for the purpose of further explaining the scope of the presentdisclosure. Other objectives and advantages related to the presentdisclosure will be illustrated in the subsequent descriptions andappended drawings.

Referring to FIG. 1, one embodiment of the present invention provides asystem Z for establishing a Serial-over-LAN connection. The system Zincludes a server unit 1 and a remote control unit 3. The server unit 1includes a computing module 10 and a baseboard management controller(BMC) 2. Specifically, both the computing module 10 and the BMC 2 aredisposed on the motherboard of the server unit 1 such that the BMC 2serves to monitor the performance of the server unit 1 and communicateswith the remote control unit 3 about the physical states of the serverunit 1. The BMC 2 has a control module 21, a first UART 22, a secondUART 23 and a network interface, i.e. the LAN interface 24. The firstUART 22 is electrically connected to the computing module 10 andconfigured to receive data from the computing module 10. In thisembodiment, the first UART 22 is disposed on the BMC chip; however, thepresent invention is not limited thereto. In other embodiments, thefirst UART 22 can be disposed on the computing module 10. The controlmodule 21 is connected between the second UART 23 and the LAN interface24, and configured to detect the current baud rate of the first UART 22,control the second UART 23 to receive the data from the first UART 22 atthe current baud rate, and send the data to a network through the LANinterface 24.

The system Z shown in FIG. 1 is used for performing the method providedin FIG. 2. With reference to both FIG. 1 and FIG. 2, when the remotecontrol unit 3 requests an SOL connection, the system Z performs thefollowing steps. Step S100: receiving data from a server unit 1 usingthe first UART 22 at a current baud rate; step S102: detecting thecurrent baud rate of the first UART 22 using the BMC 2; step S104:configuring the baud rate of the second UART 23 as the current baud rateusing the BMC 2; step S106: controlling the second UART 23 to retrievethe data from the first UART 22 at the current baud rate using the BMC;and step 108: sending the data to a network using the BMC 2.

More specifically, the control module 21 is programmed to perform stepsS102 to step S108, in which the control module 21 detects the currentbaud rate of the first UART 22 in step S102, configures the baud rate ofthe second UART 23 to be the current baud rate of the first UART 22 instep S104, controls the second UART 23 to receive the data from thefirst UART 22 in step S106, and sends the data to the network throughthe LAN interface 24 in step S108.

With the technical solution described above, the BMC 2 can performaccurate and efficient SOL connection by automatically detecting thecurrent baud rate of the first UART 22 before controlling the secondUART 23 to receive the data from the first UART 22 at the same baud rateand sending the data to the network.

The present invention is not limited by the way the BMC 2 detects thecurrent baud rate of the first UART 22. Referring to FIG. 3, in oneembodiment, step S102 can be completed by performing the following stepS200: configuring the baud rate of the second UART as an assumed baudrate using the BMC; step S202: controlling the second UART 23 toretrieve a first set of data from the first UART 22 at the assumed baudrate using the BMC; step S204: determining a switching range of the datareceived by the second UART; step S206: determining whether theswitching range of the first set of data equals 1; and step S208: if so,determining that the assumed baud rate is the current baud rate.

In the method stated above, by setting an assumed baud rate for thesecond UART 23, and scanning the data received from the first UART 22 atthe assumed baud rate to determine whether the data is receivedcorrectly, the present embodiment can detect the current baud rate ofthe first UART 22. More specifically, referring to FIG. 4A, step S204 ofFIG. 3 further includes step S300: determining the number of samplebytes of the first set of data to be used to determine the switchingrange of the first set of data; step S302: determining the number oftimes N the bit value changes within each sample byte. In the presentembodiment, the number N can be determined either by scanning bits fromthe most significant bit (MSB) to the least significant bit (LSB) orfrom the LSB to the MSB.

When the number N for one sample byte is smaller than 2, the controlmodule 21 sets the switching range of the sample byte to be an integerequal to or higher than 7 (step S304). In the embodiment shown in FIG.4A, the switching range is set to be 7; however, the present inventionis not limited thereto. When the number N for the sample byte is greaterthan or equal to 2 or less than or equal to 7, the control module 21identifies within the sample byte at least one switch unit, in whicheach switch unit has at least one bit, and each bit has the same bitvalue that is different from the bit value assigning to the bitpositions on either side of the switch unit. Afterwards, the number ofbits M within each switch unit is determined (step S306). Furthermore,for a sample byte having only one switch unit, the number M is theswitching range of the sample byte; for a sample byte having more thanone switch unit, the smallest number M is determined to be the switchingrange of the sample byte (step S308).

Please refer to FIG. 4B to FIG. 4E while step S304, step S306 and stepS308 are further described. When N is more than or equal to 2 or lessthan or equal to 7, it means that the bit value is changed at leasttwice from the MSB to the LSB within a sample byte. Therefore, at leastone switch unit A can be identified within the sample byte, in whicheach switch unit has at least one bit with a bit value different fromthat assigning to its adjacent bit positions. Taking the sample byte inFIG. 4B for example, the number N is 4, which indicates that the bitvalue has been changed from 0 to 1 or from 1 to 0 and changed backtwice, and therefore two switch units A can be found in this samplebyte. For the switch unit A on the left, the number of bits M is 2, andfor the switch unit A on the right, the number of bits M is 1. Accordingto step S308, the number 1 is determined to be the switching range ofthe sample byte 65 h. Similarly, the number 4 for the sample byte 8Ehshown in FIG. 4C is 4, the number of bits for each switch unit A thereinis 3, and thus the switching range of the sample byte 8Eh is 3. In FIG.4D, the number N is for the byte 1Eh is 2, the number of bits for theswitch unit A is 4, and thus the switching range of the byte 1Eh is 4.In FIG. 4E, since the number N is 1, which means that the bit valuechanges only once throughout the sample byte 1Fh, no switch unit isformed. According to step S304, the switching range for the sample byte1Fh is 7. The purpose of setting an integer equal to or higher than 7 instep S304 is to indicate that since a switch unit is not formed withinthe sample byte, the sample byte is not reliable to be used to determinethe baud rate. Therefore, the integer can be any other number greaterthan 7.

Regarding step S300, the present invention is not limited by the numberof sample bytes determined. A person skilled in the art can chooseaccording to actual applications. After the switching range for eachsample byte is determined, the smallest switching range among which isdetermined to be the switching range of the data (step S310). Forexample, if the number of sample bytes is determined to be 4, and thefour sample bytes 65 h. 8Eh, 1Eh, 1Fh in FIG. 4B to FIG. 4E aresuccessive and to be used to determine the switching range of a datastream, since the switching range for each of these sample bytes is 1,3, 4, and 7 respectively, the smallest number 1 is chosen to be theswitching range of the data stream.

Referring back to FIG. 3, after the switching range of the data receivedby the second UART 23 is determined, the control module 21 furtherdetermines whether the switching range equals 1. Since the number M,i.e. the number of bits within a switch unit, should be proportional tothe rate at which the UART receives serial data, if the switching rangeis 1, the assumed baud rate is determined to be the current baud rate ofthe first UART 22. Similarly, with reference to FIG. 5 and FIG. 6, whenthe switching range of the data equals 2 or 3, the baud rate of thefirst UART 22 can be determined to be half of the assumed baud rate, orone third of the assumed baud rate, respectively. Furthermore, in oneembodiment, the method of FIG. 4 can further include step S400:determining whether the switching range of the first set of data equals2, and step S402: if so, determining that half of the assumed baud rateis the current baud rate. Step S400 can be performed before step S206,and if the switching range is not 2, the control module 21 performs stepS206. In another embodiment, step S206 can be performed after step S206and the switching range does not equal 1. Moreover, in one embodiment,the method of FIG. 4 can include step S500: determining whether theswitching range of the first set of data equals 3; and step S502: if so,determining that one third of the assumed baud rate is the current baudrate. It should be noted that the present invention is not limited bythe order of performing step S206, step 400 and step S500. For instance,step S500 can be performed after step 206 and/or step 400, that is, whenit is determined that the switching range does not equal either 2 or 3,or step S500 can be performed right after the switching range isdetermined in step S204.

Referring to FIG. 7, in one embodiment wherein it is determined that theswitching range equals 4, the current baud rate of the first UART 22 canbe half of or one fourth of the assumed baud rate. Therefore, in oneembodiment, the method of FIG. 3 can further include S600: determiningwhether the switching range of the first set of data equals 4; stepS602: if so, reconfiguring the baud rate of the second UART to be halfof the assumed baud rate using the BMC; step S604: controlling thesecond UART to retrieve a second set of data from the first UART at thereconfigured baud rate using the BMC; step S606: determining theswitching range of the second set of data received by the second UART;step S608: determining whether the switching range of the second set ofdata equals 1. In the case where the current baud rate equals half ofthe assumed baud rate, the switching range determined by step S608 willbe 1, and the current baud rate is determined to be the reconfiguredbaud rate, i.e. half of the assumed baud rate (step S610). In the othercase where the current baud rate is one fourth of the assumed baud rate,the switching range determined by step S608 will be 2. Therefore, thecurrent baud rate can be determined to be one fourth of the assumed baudrate (step S612). It should be noted that step S600 can be performedbefore or after either one of step S206, step 400, and step 500.

Referring to FIG. 8 and FIG. 9, since larger switching ranges, such as 5and 6, would result in incorrect configuration of baud rate according toexperimental results, in one embodiment wherein the switching range ofthe first set of data is determined to be 5 (step S700), the baud rateof the second UART 23 is reconfigured to be one third of the assumedbaud rate (step S702), and in one embodiment wherein the switching rangeof the first set of data is determined to be equal to or greater than 6(step S800), the baud rate of the second UART 23 is reconfigured to behalf of the assumed baud rate (step S802). In some embodiments, afterthe reconfiguration of the assumed baud rate, the control module 21 maycontrol the second UART 23 to receive data from the first UART 22 at thereconfigured baud rate, and determine the switching range based on thereconfigured baud rate. If it is determined that the switching range isnot greater than or equal to 6 in step S800, then the control module 21proceeds to determine whether the switching range equals other possibleintegers smaller than 6 (step S804).

It should be noted that step S700 and step S800 can be performed beforeor after step S206, step S400, step S500 and step S600. In oneembodiment, step S800 can be performed before all said other steps so asto narrow down the possible switching range values and the efficiency ofbuilding the SOL connection can be increased, e.g. as in the embodimentof FIG. 10; however, the present invention is not limited thereto.

Referring to FIG. 10, in one embodiment, the method for detecting thecurrent baud rate of the first UART 22 when establishing an SOLconnection according to the present invention can include step S900: thecontrol module 21 configuring an assumed baud rate for the second UART23; step S902: the second UART 23 receiving data from the first UART 22at the assumed baud rate; step S904: the control module 21 determiningthe switching range P of the data received in step S902; step S906:determining whether the switching range is more than or equal to 6. Ifso, reconfiguring the baud rate for the second UART 23 to be half of theassumed baud rate (step S907) according to step S802, and then repeatingsteps S902 through step S906. If not, determining whether the switchingrange equals 1 (step S908), 2 (step S912), 3 (step S916), 4 (step S920)or 5 (step S924), which can be done in any order in other embodiments,and is not limited to the order shown in FIG. 10.

For example, in the embodiment shown in FIG. 10, step S908 is firstlyperformed, but the present invention is not limited thereto. Theperformance of step S908 leads to either the determination that thecurrent baud rate equals the assumed baud rate (step S910) according tothe method in FIG. 3, or the subsequent performance of step S912. StepS912 then results in either the determination that the current baud rateequals half of the assumed baud rate (S914) according to the method inFIG. 5, or the performance of step S916, which in turn leads to eitherstep S918 or step S920. The remaining steps shown in FIG. 10 areperformed based on the embodiments of FIG. 7 and FIG. 8; hence will notbe described again for the purpose of conciseness.

It should be noted that in the embodiments mentioned above, the currentbaud rate of the first UART 22 is determined when it is determined thatthe switching range equals 1, 2, or 3. However, the present invention isnot limited thereto. In one embodiment, as long as the switching rangedoes not equal 1, the control module 21 repeats reconfiguring the baudrate of the second UART 23 until at last the switching range equals 1.For example, in a varied embodiment of FIG. 10, after performing stepS912 and it is determined that the switching range P equals 2, thecontrol module 21 reconfigures the baud rate of the second HART 23 to behalf of the assumed baud rate and then repeats step S902 through stepS908 in order to reduce the error rate.

The above embodiments describe how the control module 21 realizesautomatic detection of the current baud rate of the first UART 22 instep S102 with the BMC 2 structure shown in FIG. 1. However, the presentinvention is not limited thereto. In a varied embodiment, referring toFIG. 11, the BMC 2 can further include a frequency detecting module 25connected between the control module 21 and the first UART 22. In thisembodiment, the control module 21 controls the frequency detectingmodule 25 to detect the current baud rate of the first UART 22 in stepS102. Detecting the baud rate using a frequency detecting component is awell-known technique in the art, and thus further details will not bedescribed herein.

In summary, the embodiments of the present invention provide a method, aBMC and a system for establishing an SOL connection, wherein by using aBMC that is able to detect the current baud rate of the first UARTautomatically, the efficiency in establishing the SOL connection isenhanced, thereby dispensing with manually configuring the baud rate forthe second UART.

The descriptions illustrated supra set forth simply the embodiments ofthe instant disclosure; however, the characteristics of the instantdisclosure are by no means restricted thereto. All changes, alterations,or modifications conveniently considered by those skilled in the art aredeemed to be encompassed within the scope of the instant disclosuredelineated by the following claims.

What is claimed is:
 1. A method for establishing a Serial-over-LAN (SOL)connection, comprising: receiving data from a server unit using a firstUART at a current baud rate; detecting the current baud rate of thefirst UART using a baseboard management controller (BMC); configuringthe baud rate of a second UART as the current baud rate using the BMC;controlling the second UART to retrieve data from the first UART at thecurrent baud rate using the BMC; and sending the data to a network usingthe BMC.
 2. The method according to claim 1, wherein the step ofdetecting the current baud rate of the first UART using the BMCincludes: configuring the baud rate of the second UART as an assumedbaud rate using the BMC; controlling the second UART to retrieve a firstset of data from the first UART at the assumed baud rate using the BMC;determining a switching range of the first set of data received by thesecond UART; determining whether the switching range of the first set ofdata equals 1; and if so, determining that the assumed baud rate is thecurrent baud rate.
 3. The method according to claim 2, wherein the stepof determining the switching range of the first set of data received bythe second UART includes: determining the number of sample bytes of thefirst set of data, wherein the sample bytes are used to determine theswitching range of the first set of data; determining the number oftimes N the bit value changes between the most significant bit (MSB) andthe least significant bit (LSB) within each sample byte; if N is smallerthan 2, setting the switching range of the sample byte to be an integerequal to or higher than 7; if N is more than or equal to 2 or less thanor equal to 7, identifying within the sample byte at least one switchunit having at least one bit, in which each bit having the same bitvalue that is different from the bit value assigning to the bitpositions on either side of the switch unit, and determining the numberof bits M within each switch unit; determining the smallest number M tobe the switching range of the sample byte; and determining the smallestswitching range among the switching ranges of all the sample bytes to bethe switching range of the first set of data.
 4. The method according toclaim 2, wherein the step of detecting the current baud rate of thefirst UART using the BMC further comprises: determining whether theswitching range of the first set of data equals 2; and if so,determining that half of the assumed baud rate is the current baud rate.5. The method according to claim 2, wherein the step of detecting thecurrent baud rate of the first UART using the BMC further comprises:determining whether the switching range of the first set of data equals2; if so, reconfiguring the baud rate of the second UART to be half ofthe assumed baud rate; controlling the second UART to retrieve a secondset of data from the first UART at the reconfigured baud rate using theBMC; determining the switching range of the second set of data receivedby the second UART; determining whether the switching range of thesecond set of data equals 1; and if so, determining that thereconfigured baud rate is the current baud rate.
 6. The method accordingto claim 2, wherein the step of detecting the current baud rate of thefirst UART using the BMC further comprises: determining whether theswitching range of the first set of data equals 3; and if so,determining that one third of the assumed baud rate is the current baudrate.
 7. The method according to claim 2, wherein the step of detectingthe current baud rate of the first UART using the BMC further comprises:determining whether the switching range of the first set of data equals4; if so, reconfiguring the baud rate of the second UART to be half ofthe assumed baud rate using the BMC; controlling the second UART toretrieve a second set of data from the first UART at the reconfiguredbaud rate using the BMC; determining the switching range of the secondset of data received by the second UART; determining whether theswitching range of the second set of equals 1; and if so, determiningthat the reconfigured baud rate is the current baud rate, and if not,determining that the current baud rate is one fourth of the assumed baudrate.
 8. The method according to claim 2, wherein the step of detectingthe current baud rate of the first UART using the BMC further comprises:determining whether the switching range of the first set of data equals5; and if so, reconfiguring the baud rate of the second UART to be onethird of the assumed baud rate using the BMC.
 9. The method according toclaim 2, wherein the step of detecting the current baud rate of thefirst UART using the BMC further comprises: determining whether theswitching range of the first set of data is greater than or equal to 6;if so, reconfiguring the baud rate of the second UART to be half of theassumed baud rate using the BMC; and if not, determining whether theswitching range of the first set of data equals to 2, 3, 4, or
 5. 10. Abaseboard management controller (BMC), comprising: a second UARTconfigured to receive data from a first UART, the first UART receivingthe data from a server unit; a control module connected to the secondUART and configured to detect a current baud rate of the first UART andcontrol the second UART to receive the data from the first UART at thecurrent baud rate; and a network interface connected to the controlmodule, configured to receive the data from the control module and sendthe data to a network.
 11. The BMC according to claim 10, furthercomprising: a frequency detecting module connected to the controlmodule, wherein the control unit is configured to control the frequencydetecting module to detect the current baud rate of the first UART. 12.The BMC according to claim 10, wherein the control module is configuredto perform the method as claimed in any one of claims 2 to
 9. 13. Asystem for establishing a Serial-over-LAN connection, comprising: aserver unit, including: a computing module; a first UART, electricallyconnected to the computing module and configured to receive data fromthe computing module; and a baseboard management controller (BMC)connected to the computing module, the BMC including: a second UARTconfigured to receive the data from the first UART; a control moduleconnected to the second UART and configured to detect a current baudrate of the first UART and control the second UART to receive the datafrom the first UART at the current baud rate; and a network interfaceconnected to the control module, configured to receive the data from thecontrol module and send the data to a network, and a remote controlunit, electrically connected to the BMC and configured to receive thedata from the network interface through the network.